It sounds like using a custom compression mechanism that exploits the structure of the data could be very efficient.

Firstly, using a `short[]`

(16 bit data type) instead of an `int[]`

will halve (!) the amount of data sent, you can do this because the numbers are easily between `-2^15`

(-32768) and `2^15-1`

(32767). This is ridiculously easy to implement.

Secondly, you could use a scheme similar to run-length encoding: a positive number represents that number literally, while a negative number represents that many zeros (after taking absolute values). e.g.

```
[10, 40, 0, 0, 0, 30, 0, 100, 0, 0, 0, 0] <=> [10, 40, -3, 30, -1, 100, -4]
```

This is harder to implement that just substituting `short`

for `int`

, but will provide ~80% compression in the very worst case (1000 numbers, 100 non-zero, none of which are consecutive).

I just did some simulations to work out the compression ratios. I tested the method I described above, and the one suggested by Louis Wasserman and sbridges. Both performed very well.

Assuming the length of the array and the number of non-zero numbers are both uniformly between their bounds, both methods save about 5400 `int`

s (or `short`

s) on average with a compressed size of about 2.5% the original! The run-length encoding method seems to save about 1 additional `int`

(or average compressed size that is 0.03% smaller), i.e. basically no difference, so you should use the one that is easiest to implement. The following are histograms of the compression ratios for 50000 random samples (they are very similar!).

**Summary**: using `short`

s instead of `int`

s and one of the compression methods, you will be able to compress the data to about 1% of its original size!

For the simulation, I used the following R script:

```
SIZE <- 50000
lengths <- sample(1000:10000, SIZE, replace=T)
nonzeros <- sample(1:100, SIZE, replace=T)
f.rle <- function(len, nonzero) {
indexes <- sort(c(0,sample(1:len, nonzero, F)))
steps <- diff(indexes)
sum(steps > 1) + nonzero # one short per run of zeros, and one per zero
}
f.index <- function(len, nonzero) {
nonzero * 2
}
# using the [value, -1 * number of zeros,...] method
rle.comprs <- mapply(f.rle, lengths, nonzeros)
print(mean(lengths - rle.comprs)) # average number of shorts saved
rle.ratios <- rle.comprs / lengths * 100
print(mean(rle.ratios)) # average compression ratio
# using the [(index, value),...] method
index.comprs <- mapply(f.index, lengths, nonzeros)
print(mean(lengths - index.comprs)) # average number of shorts saved
index.ratios <- index.comprs / lengths * 100
print(mean(index.ratios)) # average compression ratio
par(mfrow=c(2,1))
hist(rle.ratios, breaks=100, freq=F, xlab="Compression ratio (%)", main="Run length encoding")
hist(index.ratios, breaks=100, freq=F, xlab="Compression ratio (%)", main="Store indices")
```

`int[]`

s take? (I'm asking these question because the structure of the data will change what is the best compression method) – dbaupp Apr 29 '12 at 4:32